Portable computer supporting paging instructions

ABSTRACT

A portable computer is described that contains a circuit for receiving pages and performing security functions based on the received page. Once a page has been received by the portable computer, the computer&#39;s hard drive can be automatically reformatted, or the portable computer can be prevented from booting. In addition, the portable computer can be programmed to use a modem to automatically dial a security center and transmit security information such as the Caller ID Tag of the current telephone number.

RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No.10/742,619, filed on Dec. 18, 2003, which is a continuation of U.S.patent application Ser. No. 10/349,516, filed on Jan. 21, 2003, now U.S.Pat. No. 6,683,528, which is a continuation of U.S. patent applicationSer. No. 09/098,937, filed on Jun. 17, 1998, now U.S. Pat. No.6,518,874, and U.S. patent application Ser. No. 09/098,935, filed onJun. 17, 1998, now U.S. Pat. No. 6,522,242, the entirety of which arehereby incorporated herein by reference.

FIELD OF THE INVENTION

This invention relates to portable computer systems. Specifically, thisinvention relates to portable computer systems having integratedcircuits for receiving and processing paging messages.

BACKGROUND OF THE INVENTION

Over the past several years, personal communication devices such aspagers and cellular telephones have become widely used in both businessand personal environments. Fast and reliable communication has made itmuch easier for people to travel from their home or office withoutbecoming unavailable to co-workers others. The advent of portablecomputers has also encouraged this trend, as many people perform a largeamount of their duties using computing devices, and the portable or“laptop” computer further enhances the ability of people to remainproductive while traveling.

More recently, pagers have been introduced into the market withincreased data handling capabilities. As one example, the PageWriter™2000 manufactured by Motorola is a two-way pager with a keyboard andgraphical display which sends Internet e-mail and has automated messagehandling capability. In addition, computing devices have been enhancedwith additional communication capabilities. U.S. Pat. No. 5,550,861 toChan et al. for example, describes a PCMCIA format card for laptopcomputing applications, which includes an onboard modem and pager unit.

Despite these trends in combining communication and data processingcapabilities, little progress has been made in taking advantage of theavailable benefits of the combined implementation of such devices. Thecurrent state of the art consists essentially of conventionalcommunication functions coupled to conventional data processingfunctions, thereby producing one device which may combine previouslyavailable features but which does nothing to provide additionalfunctionality. In addition, advantageous hardware implementations ofsuch combinations have not been explored.

SUMMARY OF THE INVENTION

The invention comprises a portable computer, which includes a wirelessreceiver. The wireless receiver may be adapted for receiving pages. Insome embodiments, the portable computer includes a page interpretercoupled to the page receiver so as to translate selected page messagesinto commands to be executed by the portable computer.

Another embodiment of the invention comprises a computing device, whichincludes a microprocessor, a microcontroller coupled to themicroprocessor; and a wireless receiver coupled to the microcontroller.The computing device may further include a battery, coupled to themicrocontroller and the wireless receiver such that the microcontrollerand the wireless receiver are operative to receive and store messageswhen the microprocessor is in an off state.

Messages received via a page receiving circuit may in some embodimentsof the invention be classified into two groups. A volatile memorycircuit may store messages of a first group, and a non-volatile memorymay store information concerning message content for messages of asecond group. Messages of the second group may comprise commands to theportable computer.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating a portable computer systemincluding a processor, bridge chipset, microcontroller, and pager unit.

FIG. 2 is a flow diagram illustrating the process of receiving a pageand activating a user notification.

FIG. 3 is a flow diagram illustrating the process of receiving a pagercommand and performing a security function.

FIG. 4 is a flow diagram of a process of locking a computer once asecurity code has been received.

DETAILED DESCRIPTION OF THE INVENTION

The invention will now be described with reference to the accompanyingFigures, wherein like numerals refer to like elements throughout. It mayinitially be noted that the terminology used in the descriptionpresented herein is intended to be interpreted in its broadestreasonable manner, even though it is being utilized in conjunction witha detailed description of certain specific embodiments of the invention.

Embodiments of the invention include portable computers havingintegrated pager circuitry for receiving messages through a wirelesscommunication network. Although a wireless receiver is a generic circuitprovided in any type of wireless communication device including radios,cellular telephones, televisions, etc., a pager is a specific type ofwireless communication device which is adapted to receive (and sometimestransmit) numerical or alpha-numerical data over a dedicated pagerfrequency band, such as 940-941 MHz for example. As used herein, theterm “pager” refers to any wireless receiver with the capability toreceive transmissions of numerical or alpha-numerical data over adedicated paging system, whether public or private, and which may beimplemented in whole or in part through the public telephone network,satellite systems, base stations, etc. In the embodiments describedbelow, a wireless receiver which may advantageously comprise a pagerunit is integrated into a portable computer so that numerical oralpha-numerical codes can be sent to the portable computer for furtherprocessing by the portable computer.

Referring now to FIG. 1, a portable computer 10 includes a processor 20in communication with a host bus 22. The processor 20 may be anyconventional microprocessor such as an Intel Pentium, Intel Pentium II,Digital Equipment Corporation Alpha or Motorola microprocessor. The hostbus 22 communicates data between the processor 20 and a bridge circuit24. The bridge circuit 24 can include one or more discreet componentsthat provide data communication between the processor 20 and othercomponents within the personal computer 10. Bridge circuits 24incorporating the functionality shown in FIG. 1 are known in the art,and are commercially available from, for example, Intel Corp., as the430TX chipset. The bridge circuit 24 is linked to a cache memory system30 and a main memory system 32. The cache memory system 30 providesconventional cache functions for buffering data reads and writes to themain memory system 32.

In addition, the bridge circuit 24 is linked to a system management bus(SMBUS) 38 and a peripheral component interconnect (PCI) bus 40. Inconventional computers, the PCI bus transfers data between peripheraldevices and the bridge chip set 24. The SMBUS 38 provides controlsignals for managing several high-level functions within the portablecomputer 10. For example, the SMBUS 38 may communicate signalsindicative of the remaining battery power in the portable computer froma battery to the processor 20. In addition, the SMBUS 38 might providesignals relating to power management features within the portablecomputers such as screen blanking, hard disk powering, and otherfeatures that allow a portable computer to extend its battery life. Mostcommercially available laptop computers include a standard format systemmanagement bus, and further description of its structure andcommunication protocol is not required to understand the presentinvention.

In one embodiment of the invention, the system management bus 38 islinked to a microcontroller 50. The microcontroller can be anyconventional microcontroller available from several commercial sources.One suitable commercially available microcontroller is the model 68HC11from Motorola Corporation. The microcontroller 50 can store and retrievedata from a memory 52. The memory 52 can be any type of data storagedevice including Dynamic Random Access Memory (DRAM), Static RandomAccess Memory (SRAM), Erasable Programmable Read Only Memory (EPROM), orElectrically Erasable Programmable Read Only Memory (EEPROM). As will beexplained more fully below, the memory advantageously comprises abattery powered SRAM portion and an EEPROM portion. Furthermore,although illustrated in FIG. 1 as separate components, some or all ofthe memory 52 may be incorporated into the microcontroller 50. TheMotorola 68HC11 mentioned above, for example, includes internal EEPROM.In one embodiment, the memory 52 stores security codes that, whenreceived by the microcontroller 50, will be translated into a signal onthe SMBUS 38.

As shown in FIG. 1, the microcontroller 50 communicates with a pagerunit 56 having a receiving antenna 58. The pager unit 56 itself maycomprise a conventional wireless receiver circuit with the ability toreceive numeric or alpha-numeric data and transmit that data to themicrocontroller 50. These circuits are well known to those of skill inthe art, and are not described further herein.

The pager unit 56, microcontroller 50, and memory 52 may all beconnected to a dedicated battery supply 60, which is advantageouslyseparate from the battery which powers the remainder of the portablecomputer. With a separate battery supply 60, not only can pages bereceived and processed when the portable computer 10 is turned off, butpages can be received and processed even if the battery pack provided topower the portable computer as a whole is removed entirely. This featureis significant with reference to several security functions implementedas described in more detail below.

When the portable computer is paged, the pager unit answers the page,receives the message contained in the page, and sends this message tothe microcontroller 50. The microcontroller 50 stores the message in thememory 52. Due to the presence of the battery backup 60, this processcan be performed while the computer is off, or even when the mainbattery pack for the computer is removed. If several pages are receivedwhen the computer is off, the messages will continue to queue in thememory 52 until the microprocessor is available to retrieve and processthem.

It is one advantageous aspect of the invention that the messagesreceived by the pager and acted upon by the portable computer may beclassified into two distinct groups. A first group of messages comprisesinformation sent to the portable computer for viewing by the portablecomputer user. This class of page corresponds to many conventionalpaging alphanumeric messages which include telephone numbers to returnphone calls to, short textual messages from the paging party, etc. Thisclass of page also corresponds to existing “global” pages, includingstock or weather reports, or other information which is broadcast tolarge number of subscribers at approximately the same time. A secondgroup of messages comprises commands which instruct the computer toperform a function specified in the page. As will be explained below,advantageous functions performed in response to pages include securityfunctions, which may be initiated by the portable computer user with apage if the computer has been stolen.

Referring now to FIG. 2, a specific embodiment of a process 100 ofservicing pager messages is described. The process illustrated in FIG. 2is especially adapted to the reception and processing of pager messagesof the first group described above, although it will be appreciated bythose of skill in the art that many of the steps performed will be thesame for page processing of messages of both groups. The process 100begins at a start state 102 and then moves to a decision state 104 todetermine whether a page message has been received by the portablecomputer 10. When implemented with the hardware of FIG. 1, this step maybe accomplished by periodically evaluating one or more status flags inthe microcontroller 50 which are set if page message information whichhas not previously been forwarded to the microprocessor is resident inthe memory 52. If a page message has not been received, the process 100continues looping at the decision state 104 until a message is received.If a message has been received, the process 100 moves to a state 106wherein the microcontroller 50 forwards an interrupt on the SMBUS 38 tothe processor 20. The SMBUS interrupt indicates to the processor 20 thatthe microcontroller 50 has data that needs to be retrieved, and causesthe microprocessor to perform a page service subroutine.

The processor 20 then services the request made by the pagermicrocontroller 50. The process 100 moves to a state 110 wherein themessage received by the pager unit 56 and stored in the memory 52 isretrieved by the processor 20 and stored on, for example, the hard diskdrive of the portable computer. A determination is then made at adecision state 112 whether additional messages have been stored in thememory 52 which have not been retrieved by the processor 20.

If a determination is made that more messages have been received, theyare retrieved and stored at the state 110 as before. However, if moremessages have not been received the process 100 moves to a state 116wherein the user is notified that one or more pages have been received.The pages may be displayed and read with a simple text editor program orother user application software. It should be noted, however, that insome embodiments the user may not be notified of the page. For example,some types of security programs may be designed to bypass the usernotification.

Once a user notification has been activated at the state 116, theprocess 100 returns to the decision state 104 and waits for additionalpage messages to be received. It will be appreciated by those of skillin the art that many different hardware and software implementations ofthe above described procedure are possible. One alternativeimplementation may involve a memory resident page servicing programwhich automatically retrieves queued messages received since thecomputer was last powered up, and when the computer is on, periodicallypolls the microcontroller for additional page messages.

As mentioned above, it is one aspect of the invention that the portablecomputer not only receives and displays standard personal and globalpages for the computer user, but may also evaluate the content of thepage so as to interpret the page as a command to perform a particularfunction. Computer activity based on page content has not been performedprior to the present invention. Thus, a portable computer in accordancewith the present invention may include not just page reception anddisplay circuitry, but may additionally include a page contentinterpreter.

One advantageous application of this feature of the invention increasesthe security of portable computing platforms. This provides asubstantial improvement over existing laptop computers as some of theadvantages of portable computers, such as their small size and lightweight are also disadvantages in that they can be easily stolen.Increases in laptop security is one example of enhanced functionalityprovided by a computer/pager in accordance with the invention.

Specific implementations of processes by which the computer performsfunctions in response to pages are explained with reference to FIGS. 3and 4 below. Advantageously, some of these functions may be related tocomputer security. Referring now to FIG. 3, a general page implementedcomputer command procedure 108 is described. This process begins at astart state 140 and moves to a state 142 wherein the processor 20retrieves a page from the microcontroller 50. In contrast to theprocedure described in conjunction with FIG. 2, however, the content ofthe page retrieved in this case is not merely a message for the portablecomputer user, but is actually a command to be performed by the portablecomputer. Thus, in conjunction with retrieving and storing receivedpages, the page servicing routing performed by the processor 20 maysearch the alphanumeric contents of the received pages for particularstrings of characters, wherein selected strings are respectivelyassociated with selected commands to be performed by the processor 20.If a match is found, the process then moves to a state 146 wherein theprocessor performs the function requested by the page. The process thenterminates at an end state 148.

Although it will be appreciated that a wide variety of commands may beissued to the computer in this way, some specific advantageous commandsinclude commands to perform security functions in the event the portablecomputer is stolen. In one embodiment, the received page can initiate anaudible alarm from the internal speaker. In other embodiments, the ownercan send a numerical page to the portable computer, which, whenreceived, runs a more complicated security program. For example, theportable computer may, in response to a given page code, reset orreformat the hard disk drive, check the hard disk drive geometry, and/orwrite a selected pattern to all sectors of the hard disk drive. This mayeliminate not only sensitive data from the hard disk drive, but alsoapplication programs of interest to computer thieves, resulting in adecrease in value of such a portable computer to a potential thief.

Computer tracking with page codes is also possible for portablecomputers with a modem 70. In this embodiment, the portable computer maybe commanded via a page to run a security program, which periodicallydetermines if a telephone line is linked to the computer's telephonemodem 70. If a telephone line is detected, the security program mightinstruct the telephone modem 70 to turn off the speaker 74 and silentlydial a predetermined phone number of a computer at a security company orother secure location. Once the portable computer is connected to thecomputer at the security company, information can be sent related to thelocation of the portable computer. For example, in one embodiment, theportable computer may contain instructions for sending the owner's name,address and the Caller ID tag of the phone line 72 being used to makethe call to the security center. Thus, security personnel at thesecurity center will know the name of the real owner of the portablecomputer and the telephone number of the location at which the computeris currently located.

Either as a standalone security feature, or in conjunction with theabove functions, a predetermined numerical page code issued to theportable computer may additionally cause the portable computer todisable the boot process so that the computer may not be re-started. Thelocked computer is therefore useless to the thief. Reactivation of thecomputer may be implemented by sending a second page to the computerwith an alphanumeric code, which removes boot limitation set by thefirst page. In this embodiment, the BIOS may, when booting the computerat power up, retrieve one or more status bits from the memory 52 todetermine whether or not the boot sequence should be halted or modified.These status bits are in turn set when an appropriate page code isreceived by the portable computer. In some advantageous embodiments, themicrocontroller 50 is programmed to search received pages for selectedalphanumeric sequences, and in response thereto, to set or clear theabove mentioned status bits accordingly. The memory 52 may include someEEPROM memory to store these status bits so that they will not be erasedeven if the computer battery pack and the additionalpager/microcontroller battery 60 are removed. It can thus be appreciatedthat in some embodiments of the invention, at least some pageinterpretation, and processing, in addition to the function of storingpage messages for later retrieval, may be done by the microcontroller50, rather than only by the microprocessor 20. The portable computer mayadvantageously include a page receiver setup program which allows theuser to choose the codes that either the microcontroller 50 and/ormicroprocessor 20 will interpret as selected security commands. Accessto this program may itself be password protected to inhibit thieves orother unauthorized users from reprogramming these security codes.

A specific example of a BIOS boot sequence in accordance with thisimplementation of the invention is provided in FIG. 4. Referring now tothis Figure, a boot process 150 begins at a start state 152 and thenmoves to a state 154 when the portable computer 10 is turned on. Theprocess 150 then moves to a state 156 wherein the computer BIOSretrieves a status code from the microcontroller 50. As discussed above,this status code may comprise a security code which has been set to aparticular configuration and stored in the memory 52 in response to aprior page sent to the portable computer by the user. As is known in theart, the Basic Input/Output System (BIOS) is firmware that controls acomputer's bootup sequence. The BIOS is normally stored in aprogrammable read only memory such an EPROM or EEPROM. Thus, the BIOScan be programmed at the factory to search for a particular securityflag during every boot. Once the BIOS has read a security code from themicrocontroller or its associated memory, the process 150 moves to adecision state 160 to determine whether the status of the computer isokay. Thus, if the computer has received a numerical or alpha-numericalpage instructing the computer to no longer boot, the microcontroller 50asserts a flag instructing the BIOS to bypass the bootup sequence. Thus,at the decision state 160, a determination is made whether such a lockuppage code has been received.

If the status is okay at the decision state 160, the process 150completes the boot sequence at a state 164. However, if the status isnot okay, indicating that a security page has been received, the process150 aborts the normal boot sequence at a state 166 and then proceeds toa decision state 170 to determine whether an additional security commandhas been stored in the memory 52. The additional command, for instance,might be to instruct a telephone modem within the portable computer 10to dial a predetermined telephone number and transmit the Caller ID tagof the phone where the portable computer is located. As one alternativeexample, the additional command may instruct the portable computer toreformat the hard disk drive.

If a determination is made at the decision state 170 that a storedsecurity command should be performed, the process 150 moves to a state174 wherein the command is performed. However, if a determination ismade at the decision state 170 that an additional security command hasnot been stored by the user via page the boot process of the portablecomputer 10 is terminated at a state 176. Once a security command hasbeen performed at a state 174 (if required), the process of booting isalso terminated at the state 176. Thus, if the portable computer hasreceived a predetermined code that is associated with themicrocontroller 50 preventing the portable computer 10 from booting, theportable computer will continue to terminate its boot sequence at thestate 176. It can be appreciated that if the computer is laterrecovered, an additional, different code can be sent to the pager unit56 to instruct the microcontroller 50 to clear the status code set withthe prior page to indicate that the status of the computer at thedecision state 160 is now okay. Thus, the computer will no longer beprevented from booting. Defeating the above described security system isvery difficult for a computer thief. Without knowledge of the pagesecurity codes programmed in by the user, the thief cannot clear any setsecurity flags. Furthermore, the dedicated battery supply 60 preventsthe thief from blocking the reception of a security page by removing thecomputer battery pack.

The following scenario describes one type of security function which maybe performed by embodiments of the portable computer. The owner of aportable computer may send a pager code to the portable computer afterrealizing that it has been stolen. To send a page, the owner dials atelephone number corresponding to the pager unit 56, and enters in thepredetermined security code such as “99999”. The code “99999” mayinstruct the computer to terminate any future boot sequence andre-format the hard disk drive to prevent access to any sensitive datapresent there.

In a few moments, the pager unit 56 receives the code “99999” andtransfers that code to the microcontroller 50. If the portable computeris turned off, the battery 60 continues providing power to the pager 56,microcontroller 50, and memory 52 so that pages may be received andprocessed.

As can be appreciated from the discussion presented above, the page“99999” may be processed by the portable computer in a variety of ways.For example, the microcontroller 50 firmware may initially evaluate thecontent of the page to determine if the “99999” code corresponds to aparticular pre-determined function or comprises simply a typicalalphanumeric message for the computer user. If the microcontrollerfirmware identifies the code “99999” as being a security code, it mayset one or more EEPROM status bits that are later evaluated by the BIOSof the portable computer so as to instruct the microprocessor 20 to exitthe normal boot sequence and initiate a low-level format of the harddrive. Alternatively, the microcontroller 50 may not be programmed toevaluate the content of the pages received, and may simply store the“99999” in memory 52 for later retrieval and interpretation by themicroprocessor 20.

If the portable computer is powered up at the time this page code“99999” is received, the microcontroller 50 may forward this code to theprocessor as part of the usual page processing program. The receivedpage codes may be evaluated by the processor 20 to check for codes suchas the “99999” and, when received, cause the processor 20 to beginreformatting the hard drive.

It can be appreciated that many types of functions may be performed bythe microcontroller 50 and/or the microprocessor 20 once a page has beenreceived. The microcontroller 50 or an associated memory could storehundreds of codes, with each code being associated with a particularfunction to be carried out once the page is received.

While the invention has been described in connection with specificembodiments thereof, it will be understood that it is capable of furthermodification, and this application is intended to cover any variations,uses, or adaptations of the invention following, in general, theprinciples of the invention and including such departures from thepresent invention as would be understood to those in the art asequivalent and the scope and context of the present invention is to beinterpreted as including such equivalents and construed in accordancewith the claims appended hereto.

1. A method of manufacturing a device having security functions, themethod comprising: configuring the device to receive information via awireless receiver, such that the wireless receiver is operative when thedevice is otherwise powered down; providing a resettable status flag ina memory of the device, the resettable status flag having a first stateand a second state and such that the status flag can be stored when thedevice is otherwise powered down; configuring a processor of the deviceto set the status of the resettable status flag to the first state orthe second state in response to the information received via thewireless receiver; and providing the device with computer instructionsthat, when executed by the processor during a boot sequence followingmain power up of the device, perform a security function that comprises:determining the status of the resettable status flag; if the resettablestatus flag is in the first state, aborting the boot sequence;determining whether the device is connected to one of a plurality ofphone lines of a communications network via a modem; and if the deviceis connected to one of the plurality of phone lines, transmitting acaller ID tag of the one phone line indicative of the location of thedevice with the modem after terminating the boot sequence.
 2. The methodof claim 1, wherein the wireless receiver is located in the device.
 3. Adevice comprising: a resettable status flag storable in a memory of thedevice, the resettable status flag configured to have a first state anda second state; a wireless receiver configured to receive boot sequenceinformation, wherein the boot sequence information identifies the firststate or the second state, the first state associated with at least onestored security command, wherein the wireless receiver and at least aportion of the memory are operative to receive the boot sequenceinformation and to store the resettable status flag when the device isotherwise powered down; and a processor configured to set the status ofthe resettable status flag to the first state or the second state inresponse to the boot sequence information received via the wirelessreceiver, the processor further configured to determine the status ofthe resettable status flag during a boot sequence, the processor furtherconfigured to terminate the boot sequence if the status of theresettable status flag is set to the first state, the processor furtherconfigured to initiate execution of the at least one stored securitycommand after terminating the boot sequence.
 4. The device of claim 3,wherein the boot sequence information comprises a plurality ofalphanumeric characters.
 5. The device of claim 4, wherein the bootsequence information contains at least one string of characters that isassociated with a boot sequence operation.
 6. The device of claim 4,wherein the boot sequence information contains at least one string ofcharacters that is associated with a plurality of boot sequenceoperations.
 7. The device of claim 3, wherein the boot sequenceinformation comprises a flag bit.
 8. A device comprising: means forreceiving information; means for storing a resettable status flag, theresettable status flag having a first state and a second state, whereinthe means for storing are operative to store the resettable status flagand such that the device can receive the information when the device isotherwise not operative; means for configuring a processor of the deviceto set the status of the resettable status flag to the first state orthe second state in response to the information received via thewireless receiver; and means for providing the device with computerinstructions that, when executed by the processor during a bootsequence, perform a security function that comprises: means fordetermining the status of the resettable status flag; if the resettablestatus flag is in the first state, means for aborting the boot sequence,means for determining whether the device is connected to one of aplurality of phone lines of a communications network via a modem; and ifthe device is connected to one of the plurality of phone lines, meansfor transmitting a caller ID tag of the one phone line indicative of thelocation of the device with the modem after aborting the boot sequence.9. The device of claim 8, wherein wireless receiver is located in thedevice.
 10. A method of manufacturing a device having securityfunctions, the method comprising: configuring the device to receiveinformation, such that the information can be received when the deviceis otherwise powered down; providing a resettable status flag in atleast a portion of memory of the device, the resettable status flaghaving a first state and a second state such that the resettable statusflag can be stored when the device is otherwise powered down;configuring a processor of the device to set the status of theresettable status flag to the first state or the second state inresponse to the information received; and providing the device withcomputer instructions that, when executed by the processor, perform asecurity function that comprises: terminating the boot sequence if thestatus flag is in the first state; and transmitting a caller ID tag of aphone line indicative of the location of the device with a modem whenthe device is connected to a communication network via the modem throughthe phone line after terminating the boot sequence.
 11. The method ofclaim 10, wherein further comprising a wireless receiver is located inthe device and wherein the wireless receiver and the at least portion ofthe memory are operative when the device is otherwise powered down. 12.The method of claim 10, wherein performing the security function furthercomprises turning off a speaker associated with the modem when thedevice is connected to the communication network via the modem throughthe phone line and when the flag is in the first state.
 13. The methodof claim 10, wherein performing the security function further comprisesperiodically determining when the modem is connected to thecommunication network.
 14. The method of claim 10, wherein the receivedinformation is from a pager.
 15. The method of claim 1, whereinperforming the security function further comprises completing the bootsequence if the resettable status flag is in the second state.
 16. Thedevice of claim 8, wherein performing the security function furthercomprises completing the boot sequence if the resettable status flag isin the second state.
 17. The method of claim 10, wherein performing thesecurity function further comprises completing a boot sequence when theresettable status flag is in the second state.
 18. The method of claim1, further comprising connecting a first power supply to the device toprovide main device power and such that the wireless receiver isoperative and the status flag can be stored when the first power supplyis disconnected from the device.
 19. The device of claim 3 furthercomprising a first power supply connected to the device to provide maindevice power and wherein the wireless receiver and the at least aportion of the memory are operative to receive the boot sequenceinformation and to store the resettable status flag when the first powersupply is disconnected from the device.
 20. The device of claim 19,wherein the first power supply comprises a battery such that the devicecomprises a portable device.
 21. The device of claim 8, furthercomprising first means for supplying power connected to the device toprovide main device power and wherein the means for receivinginformation and the means for storing are operative to receive the bootsequence information and to store the resettable status flag when thefirst means for supplying power are disconnected from the device. 22.The method of claim 10, further comprising connecting a first powersupply to the device to provide main device power and such that theinformation can be received and such that the resettable status flag canbe stored when the first power supply is disconnected from the device.